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Meeting Abstracts  |   April 1996
Anesthetic Potency of Remifentanil in Dogs
Author Notes
  • (Michelsen) Assistant Professor of Anesthesiology.
  • (Salmenpera) Visiting Assistant Professor of Anesthesiology. Current position: Department of Anesthesia, Helsinki Central Hospital, Helsinki, Finland.
  • (Hug) Professor of Anesthesiology and Pharmacology; Director, Division of Cardiothoracic Anesthesia.
  • (Szlam) Research Associate.
  • (VanderMeer) Fellow in Cardiothoracic Anesthesia. Current position: Department of Anesthesia, University of Leiden Hospital, Leiden, The Netherlands.
  • Received from the Department of Anesthesiology, Emory University, Atlanta, Georgia. Submitted for publication June 27, 1995. Accepted for publication October 26, 1995. Supported by a grant from Glaxo Inc. Presented in part at the annual meeting of the American Society of Anesthesiologists, New Orleans, Louisiana, October 17-21, 1992.
  • Address reprint requests to Dr. Hug: Department of Anesthesiology, Emory University Hospital, 1364 Clifton Road, Atlanta, Georgia 30322.
Article Information
Meeting Abstracts   |   April 1996
Anesthetic Potency of Remifentanil in Dogs
Anesthesiology 4 1996, Vol.84, 865-872.. doi:
Anesthesiology 4 1996, Vol.84, 865-872.. doi:
Key words: Anesthetics, intravenous: remifentanil. Anesthetics, volatile: enflurane. Antagonists: naloxone. Opioids: remifentanil. Potency: minimum alveolar concentration.
THE use of opioids in anesthetic practice is predicated on their ability to block sympathetic (hypertension, tachycardia) and somatic (coughing, movement) responses to noxious stimulation. Administration of an opioid to a target range of plasma concentrations can block responsiveness to nociceptive stimuli for many patients. [1,2] However, the use of opioids alone to prevent responses to noxious stimulation requires the administration of large doses for a prolonged time in some patients, resulting in accumulation of opioid and prolonged recovery from its effects, especially respiratory depression.
Remifentanil, the hydrochloride salt of 3-[4-methoxy-carbonyl-4-[(1-oxopropyl) phenylamino]-1-piperidine] propanoic acid methyl ester, formerly designated as GI87084B, is a new synthetic opioid exhibiting micro-opioid receptor-mediated effects, analogous to those of structurally related phenylpiperidine derivatives such as fentanyl and sufentanil. [3] The unique characteristic of remifentanil is the propanoic acid methyl ester linkage on the piperidine nitrogen, which renders it susceptible to metabolism by nonspecific esterases in blood and tissues. The terminal half-life of remifentanil in humans ranges from 10 to 21 min, and a computer simulation showed that its context-sensitive half-time is less than 5 min no matter how large the dose or how long the infusion. [4] Remifentanil is distinguished from the rest of the phenylpiperidine opioids by not only having a rapid onset and a short latency to its peak effect but also a rapid recovery. With these characteristics, remifentanil should facilitate administration by either variable-rate infusion titrated to individual patient needs or a constant-rate infusion targeted at the EC99(the drug concentration that will produce a given effect in 99% of the subjects) for suppression of responses to all intensities of noxious stimulation.
The minimum alveolar concentration (MAC) at which an inhaled anesthetic agent suppresses the response to a standard stimulus in 50% of the subjects is used as a measure of anesthetic potency. The ability of opioids to reduce the MAC of enflurane in dogs facilitates comparisons of opioids and other drugs in terms of their anesthetic potency and efficacy. [5-7] For drugs with contrasting pharmacokinetic profiles (e.g., fentanyl vs. remifentanil), a comparison can be established by maintaining stable plasma concentrations. Responses to tail-clamping in dogs seems also to allow extrapolation to the equivalent stimulus of skin incision in humans. [8] .
Materials and Methods
The study was approved by the Emory University Animal Use and Care Committee and followed the guidelines established by the National Institutes of Health for the ethical use of animals in research.
Mongrel dogs (N = 25) weighing 19.9+/-3.3 kg (SD) were given an intravenous dose of 0.1 mg/kg succinylcholine mixed with 0.015 mg/kg glycopyrrolate, and anesthesia was simultaneously induced with 5% enflurane in oxygen using a specialized mask and a Bain anesthesia circuit. Succinylcholine permitted immediate administration of a high concentration of enflurane and facilitated a rapid induction without the potential discomfort that the animal may experience while struggling during a slower induction. [9] A cuffed tube was placed in the trachea and mechanical ventilation was controlled by a Harvard respirator (South Natick, MA), adjusted to maintained normocarbia as determined by arterial blood gases. Lactated Ringer's solution was infused through a foreleg intravenous cannula at a rate of 4 ml *symbol* kg sup -1 *symbol* h sup -1. An esophageal probe allowed monitoring of body temperature, which was maintained through the use of a warming blanket within 1 degree C of the temperature measured after induction of anesthesia. The electrocardiogram was monitored continuously. A percutaneous femoral artery catheter was used for continuous blood pressure monitoring on a strip chart recorder and for periodic sampling of arterial blood for gas analysis and determination of whole blood concentrations of remifentanil and its principal metabolite (GR90291). The blood volume removed was replaced by an equal volume of 5% albumin injected intravenously after each sample.
Assessment of Anesthesia
End-tidal enflurane concentration was measured with a Beckman LB-2 (Fullerton, CA) infrared analyzer calibrated before each experiment. The tail-clamp method was used to determine enflurane MAC. [5] Expired enflurane was adjusted in 0.2% increments or decrements. Minimum alveolar concentration was defined as the end-tidal concentration midway between the end-tidal concentrations of enflurane at which the animal did and did not move in response to the applied stimulus.
To determine the concentrations of remifentanil and its main metabolite in whole blood, 1-ml aliquots of arterial blood were immediately placed in two volumes of acetonitrile (first 11 animals) or 50% citric acid solution (last 14 animals) to arrest esterase activity followed by four volumes of methylene chloride to extract remifentanil and the metabolite into the organic phase. The samples were then stored at -70 degrees C until the time of analysis. Blood concentrations of remifentanil were determined by gas chromatography with high-resolution mass spectrometry and selective ion monitoring (GC-HRMS-SIM) [10] and duplicate samples were analyzed by high-pressure liquid chromatography (see Appendix) and verified by the manufacturer (Glaxo, Research Triangle Park, NC).
Experimental Protocol
After waiting at least 1 h after the induction of enflurane anesthesia, control enflurane MAC was determined. In the first set of experiments, six dogs received incremental infusions of remifentanil (Glaxo) at rates from 0.055 to 5.5 micro gram *symbol* kg sup -1 *symbol* min sup -1. When each infusion rate had been constant for 30 min, enflurane MAC was determined and an arterial blood sample was obtained for remifentanil assay. After the entire infusion sequence was completed, the infusion rate was decreased to that previously causing a 30-40% decrease of enflurane MAC, and MAC was again determined at that infusion rate. Finally, the remifentanil infusion was stopped and the last measurement of MAC was obtained 30 min later.
In the second set of experiments, the stability of remifentanil blood concentrations and the MAC-reducing effect were evaluated during a prolonged constant rate infusion of 0.6 micro gram *symbol* kg sup -1 *symbol* min sup -1 in five dogs, and 1.0 micro gram *symbol* kg sup -1 *symbol* min sup -1 in eight dogs. Remifentanil concentrations and enflurane MAC were determined before and every hour after starting the infusion.
In the third set of experiments, infusions of 0.5 and 1.0 micro gram *symbol* kg sup -1 *symbol* min sup -1 were alternated repeatedly in six dogs to determine the consistency of the MAC reduction with each infusion rate and blood concentration over time. Remifentanil concentration and enflurane MAC were determined at least 1 h after each change in the infusion rate.
At the end of either a continuous infusion or an alternating sequence of infusion rates, 0.1 mg/kg naloxone was given, enflurane MAC determined and compared to the control MAC in 13 of the dogs. In six dogs, the remifentanil infusion was stopped, and 30 min later MAC was determined and compared to control MAC.
Data Analysis and Statistics
Remifentanil infusion rates and blood concentrations versus enflurane MAC reductions were fitted to a nonlinear Emaxregression model [11] : Equation 1where E = % reduction of enflurane MAC, C = remifentanil blood concentration, Emax= maximum obtainable enflurane MAC reduction, and EC50= remifentanil blood concentration when enflurane MAC was reduced by 50% and gamma = dimensionless exponent that determines the slope of the concentration-effect curve. In the dose-response analysis, concentrations of remifentanil were replaced by the infusion/rates dose. Linear regression was used to assess the correlations between remifentanil infusion rate and its blood concentrations. Analysis of variance followed by Scheffe's F test was used to compare values at the different measurement points, and P < 0.05 was considered statistically significant. Values are expressed as mean+/-SD.
Results
Incremental changes in the remifentanil infusion rate produced proportional increases in remifentanil concentrations in blood (Figure 1). Control enflurane MAC before remifentanil administration was 2.1 +/-0.2%. Enflurane MAC was reduced by all remifentanil doses, with a 63.0+/-10.4% reduction at the infusion rate of 1.0 micro gram *symbol* kg sup -1 *symbol* min sup -1. Higher infusion rates produced only small additional decreases in MAC that were not statistically significant. When infusion rates were related to the corresponding enflurane MAC reductions in a nonlinear Emaxmodel, a maximum reduction of 71.4% was predicted (Figure 2). The dose producing a 50% reduction in the enflurane MAC solved from the same regression equation was 0.715 micro gram *symbol* kg sup -1 *symbol* min sup -1 (95% confidence limits 0.687-0.743 micro gram *symbol* kg sup -1 *symbol* min sup -1). A ceiling to the enflurane MAC reduction also was apparent when blood concentrations were at and greater than 10-15 ng/ml (Figure 3). The concentration versus response curve describing the Emaxmodel predicted a maximum MAC reduction of 75.1%. The EC50was 9.2 ng/ml (95% confidence limits 8.39-10.01 ng/ml). The MAC measured at the end of the experiments after stopping remifentanil infusion with and without injection of naloxone was 2.1+/-0.19%, which was not different from the control enflurane MAC.
Figure 1. Correlation between remifentanil infusion rate in micrograms per kilogram per minute and blood concentration of remifentanil in nanograms per milliliter using linear regression (R = 0.88).
Figure 1. Correlation between remifentanil infusion rate in micrograms per kilogram per minute and blood concentration of remifentanil in nanograms per milliliter using linear regression (R = 0.88).
Figure 1. Correlation between remifentanil infusion rate in micrograms per kilogram per minute and blood concentration of remifentanil in nanograms per milliliter using linear regression (R = 0.88).
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Figure 2. Remifentanil dose versus effect: infusion rate in micrograms per kilogram per minute versus percent reduction of enflurane minimum alveolar concentration relationship as analyzed by nonlinear regression. ED50is the dose causing 50% reduction of enflurane minimum alveolar concentration.
Figure 2. Remifentanil dose versus effect: infusion rate in micrograms per kilogram per minute versus percent reduction of enflurane minimum alveolar concentration relationship as analyzed by nonlinear regression. ED50is the dose causing 50% reduction of enflurane minimum alveolar concentration.
Figure 2. Remifentanil dose versus effect: infusion rate in micrograms per kilogram per minute versus percent reduction of enflurane minimum alveolar concentration relationship as analyzed by nonlinear regression. ED50is the dose causing 50% reduction of enflurane minimum alveolar concentration.
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Figure 3. Remifentanil concentration versus effect (blood concentration in nanograms per milliliter versus percent reduction of enflurane minimum alveolar concentration) relationship as analyzed by nonlinear regression. EC50is the concentration causing 50% reduction of enflurane minimum alveolar concentration.
Figure 3. Remifentanil concentration versus effect (blood concentration in nanograms per milliliter versus percent reduction of enflurane minimum alveolar concentration) relationship as analyzed by nonlinear regression. EC50is the concentration causing 50% reduction of enflurane minimum alveolar concentration.
Figure 3. Remifentanil concentration versus effect (blood concentration in nanograms per milliliter versus percent reduction of enflurane minimum alveolar concentration) relationship as analyzed by nonlinear regression. EC50is the concentration causing 50% reduction of enflurane minimum alveolar concentration.
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The main hemodynamic change produced by remifentanil was a dose-dependent decrease in heart rate, which was reduced by approximately 35% compared to the baseline heart rate with enflurane alone. Near maximal decreases occurred at infusion rates of 0.6 micro gram *symbol* kg sup -1 *symbol* min sup -1 or less (Figure 4). The mean arterial pressure did not vary significantly with remifentanil, although there was a tendency toward higher systolic and lower diastolic arterial pressures along with the slower heart rate. Naloxone completely antagonized the heart rate reductions caused by remifentanil.
Figure 4. Heart rate and reduction of enflurane minimum alveolar concentration as functions of remifentanil dose rate in micrograms per kilogram per minute. Each line represents data for an individual animal (n = 6, the first set of experiments).
Figure 4. Heart rate and reduction of enflurane minimum alveolar concentration as functions of remifentanil dose rate in micrograms per kilogram per minute. Each line represents data for an individual animal (n = 6, the first set of experiments).
Figure 4. Heart rate and reduction of enflurane minimum alveolar concentration as functions of remifentanil dose rate in micrograms per kilogram per minute. Each line represents data for an individual animal (n = 6, the first set of experiments).
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Prolonged infusions of remifentanil produced a persistent reduction of enflurane MAC with no trend or significant change in the degree of MAC reduction over time (Figure 5). There was a statistically significant difference between the MAC reduction produced by an infusion of 0.5 micro gram *symbol* kg sup -1 *symbol* min sup -1 and that of 1.0 micro gram *symbol* kg sup -1 *symbol* min sup -1 of remifentanil, and this difference was maintained over time even when the infusion rates were alternated (Figure 6).
Figure 5. Enflurane minimum alveolar concentration reduction with remifentanil over time: effect of 1.0 micro gram *symbol* kg sup -1 *symbol* min sup -1 (n = 8). Error bars represent+/-the SD.
Figure 5. Enflurane minimum alveolar concentration reduction with remifentanil over time: effect of 1.0 micro gram *symbol* kg sup -1 *symbol* min sup -1 (n = 8). Error bars represent+/-the SD.
Figure 5. Enflurane minimum alveolar concentration reduction with remifentanil over time: effect of 1.0 micro gram *symbol* kg sup -1 *symbol* min sup -1 (n = 8). Error bars represent+/-the SD.
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Figure 6. Consistency of enflurane minimum alveolar concentration reduction with remifentanil infusion of 1.0 (open circles) and 0.5 (dark circles) micro gram per kilogram per minute. Error bars show+/-SD for the eight dogs.
Figure 6. Consistency of enflurane minimum alveolar concentration reduction with remifentanil infusion of 1.0 (open circles) and 0.5 (dark circles) micro gram per kilogram per minute. Error bars show+/-SD for the eight dogs.
Figure 6. Consistency of enflurane minimum alveolar concentration reduction with remifentanil infusion of 1.0 (open circles) and 0.5 (dark circles) micro gram per kilogram per minute. Error bars show+/-SD for the eight dogs.
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Analysis of the principal metabolite of remifentanil (GR90291) in the dogs receiving prolonged infusions showed that its concentration increased over time reaching a plateau 4 or 5 h after starting the infusion of remifentanil. The peak concentrations measured were 77.0 +/-4.4 ng/ml (Figure 7). The concentration of GR90291 started to decline at 450-500 min, the period when remifentanil was decreased to 0.5 micro gram *symbol* kg sup -1 *symbol* min sup -1, and continued to decrease slowly after discontinuation of remifentanil.
Figure 7. Concentration in nanograms per milliliter of blood of the main metabolite of remifentanil (GR90291) over time (in min) in dogs receiving prolonged infusions of remtfentanil (n = 6). The dotted area represents the period where the remifentanil infusion was decreased by 50%. After measuring minimum alveolar concentration at this level, the remifentanil infusion was stopped.
Figure 7. Concentration in nanograms per milliliter of blood of the main metabolite of remifentanil (GR90291) over time (in min) in dogs receiving prolonged infusions of remtfentanil (n = 6). The dotted area represents the period where the remifentanil infusion was decreased by 50%. After measuring minimum alveolar concentration at this level, the remifentanil infusion was stopped.
Figure 7. Concentration in nanograms per milliliter of blood of the main metabolite of remifentanil (GR90291) over time (in min) in dogs receiving prolonged infusions of remtfentanil (n = 6). The dotted area represents the period where the remifentanil infusion was decreased by 50%. After measuring minimum alveolar concentration at this level, the remifentanil infusion was stopped.
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Discussion
The ability to reduce the MAC of volatile anesthetics is a measure of the anesthetic activity of all central nervous system depressants, and it allows comparisons of both potency (dose or concentration for a given MAC reduction) and efficacy (maximum obtainable MAC reduction). In the standard dog model of MAC reduction, we found that remifentanil had significant anesthetic activity. Table 1compares the enflurane MAC reduction produced by different opioids in the same dog model. [12,5-7] Like other opioids, the maximum MAC reduction approximated 70%, which was unchanged by two or three times larger doses (ceiling effect). Although the extremely rapid clearance of remifentanil allows a rapid recovery even after large doses are given, it is unlikely that this drug alone could be used as a complete anesthetic because the limiting factor will be the maximum intrinsic activity inherent in all micro-type opioids.
Table 1. Enflurane Minimum Alveolar Concentration Reduction in Dogs with Different Opioids
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Table 1. Enflurane Minimum Alveolar Concentration Reduction in Dogs with Different Opioids
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Prolonged infusions of remifentanil resulted in a sustained MAC reduction over time and there was no evidence of tolerance. The use of alternating rates showed that the amount of MAC reduction for a given infusion rate remained unchanged and predictable throughout the experiment. This confirms the lack of remifentanil accumulation at the doses and time intervals used in these experiments. No trends were evident to suggest that either tolerance to or accumulation of remifentanil would occur at other infusion rates or duration of infusion.
The rapid clearance of remifentanil is dependent on enzymatic hydrolysis by esterases. At the extremely high infusion rates used in some of our experiments, there was no evidence of saturation of the enzymatic process; recovery to control enflurane MAC occurred in less than 30 min, the earliest time at which MAC measurements were made after stopping infusion of remifentanil.
The main remifentanil metabolite is the deesterified carboxylic acid (GR90291). It is a pure micro-agonist with a potency 1/2000 to 1/4000 that of remifentanil. [13-15] Pharmacokinetic analysis in humans shows that this metabolite has a terminal half-life six or seven times longer and a steady-state concentration 12 times higher than that of remifentanil. [4] In theory, if enough metabolite accumulates it could bind to the micro-receptors, producing a long-lived duration of effect. That the effect of remifentanil did not change during prolonged infusions and that the MAC reduction seen paralleled the concentration of remifentanil and not that of GR90291 suggests that the metabolite does not alter the effect of remifentanil administered in this dose range and over a 6-8-h duration of the infusion. The concentrations of metabolite measured during the study did not exceed 80 ng/ml whereas simultaneous remifentanil concentrations were 9-12 ng/ml. Because the metabolite is such a weak agonist, these concentrations are too low to provide any significant additive effect to the action of remifentanil.
Titration of remifentanil to effect is facilitated by a rapid blood-brain equilibration.* Rapid clearance from effect sites (context sensitive half-time = 3.7 min) even after large doses and long infusions suggests that remifentanil may be suitable for long surgical procedures and postoperative sedation. [4] Two-stage infusion schemes may not be necessary, because, during constant rate infusion, 50% of the target blood concentration is reached in 1.3 min. [4] Virtual steady-state concentrations undoubtedly prevailed in this study in which MAC determinations were not done until 30 min had elapsed from the change in the infusion rate and no differences were noted when subsequent MAC measurements were made at the same infusion rate. The reduction of enflurane MAC by remifentanil completely disappeared either after administration of naloxone or less than 30 min (earliest measurement) after stopping the infusion.
The use of opioids in anesthetic practice is predicated on their ability to block sympathetic (hypertension, tachycardia) and somatic (coughing, movement) responses to noxious stimulation. For a number of reasons (variability in dosage requirements among patients and within an individual patient; variable intensities of stimulation; lack of a graded method to monitor opioid effect, especially in a paralyzed patient; greater difficulty in reversing a response to stress than in preventing it; and absence of dose-related side effects and toxicity in a tracheally intubated patient whose lungs are mechanically ventilated), the anesthesiologist finds it more reliable and convenient to employ opioids in large doses as primary anesthetic agents and to maintain opioid concentrations at the upper levels of their therapeutic ranges. The larger the dose and the longer the maintenance of high concentrations of presently available opioids, the greater their accumulation in the body and the longer the time required for recovery from their effects, especially ventilatory depression. [2,4] Precise titration of opioid administration according to the individual patient's needs is difficult for the reasons cited earlier and often is impractical because of the pharmacokinetic characteristics of the opioids that are currently available. Remifentanil provides an attractive alternative because the effects of large doses that decrease or suppress responses to stimulation in the majority of the patients (EC99) disappear rapidly once the infusion of remifentanil is stopped.
The steady-state plasma concentrations required to suppress the response to a given stimulus are used to compared the anesthetic potency of drugs. In terms of MAC, tail clamping in dogs is believed to be a stimulus equivalent to surgical skin incision in humans. [8] Enflurane MAC reduction by different opioids provides a basis for comparison of their potency, and this datum also suggests that the anesthetic potencies of opioids in humans and dogs are similar. [1,6] Because of the way remifentanil is metabolized, the concentration of remifentanil has to be measured in whole blood instead of plasma, and the distribution of remifentanil between blood cells and plasma is not known. The blood concentration of remifentanil causing 50% enflurane MAC reduction (EC50) was 9.2 ng/ml, whereas this same effect is produced by a fentanyl plasma concentration of 5.5 ng/ml in the dog. [16] Using the established partition coefficient of fentanyl and mean hematocrit value for dogs (0.49 +/-0.05), a plasma fentanyl concentration of 5.5 ng/ml would correspond to a whole blood concentration of 5.16 ng/ml. [17] On this basis, remifentanil appears to be about one half as potent as fentanyl. Applying the same logic to alfentanil (EC50 = 54 ng/ml of plasma or 33.6 ng/ml of whole blood), the corresponding blood concentration ratio between alfentanil and remifentanil should be 3.6:1. So far, there are limited studies to compare these results. Studies showing a remifentanil EC50 of 14.7-19.5 ng/ml for shifting of the spectral edge in human volunteers are in accordance with our results. [18],* However, a potency ratio of 32:1 between alfentanil and remifentanil blood concentrations was found in a study achieving equivalent depression of the respiratory minute-volume.** Clearly, valid comparisons of the relative potencies of opioids mandate the use of similar endpoints or stimuli against which those comparisons are made.
Remifentanil, like other opioids, caused a dose-dependent reduction of the heart rate. Most of this effect was evident at small doses and the dose-response curve for heart rate reduction had a steeper slope and peaked at a lower concentration than the anesthetic-sparing effect. A decrease in heart rate was typically observed when remifentanil was administered with isoflurane for induction of anesthesia in humans.*** No consistent changes in blood pressure were observed in this study in which the measurements were always made at equivalent (1 MAC) levels of anesthesia.
In conclusion, the potency of remifentanil is about one half that of fentanyl, judging by the blood concentrations producing equivalent decreases in the enflurane MAC in dogs. Remifentanil is no more efficacious than other opioids of the piperidine family, with a ceiling effect close to 70%. Its effect over time is sustained and recovery is rapid even after prolonged infusion.
Appendix
Blood samples (3 ml) were collected in heparinized Vacutainer tubes (Becton-Dickinson, Rutherford, NJ). A 1-ml aliquot was pipetted into a glass tube containing 20 micro liter of 50% citric acid and vortexed to ensure mixing. Samples were kept frozen at -70 degrees C until analysis (1-8 weeks). At the time of analysis, 2 ml acetonitrile and 50 ng fentanyl (as an internal standard) were added to each sample. After vortexing, 5 ml methylene chloride was added. Samples were mixed by vortexing, and centrifuged for 5 min at 1000g to aid in clean separation of the layers. The lower organic layer was removed and applied to a Extrelut QE column (EM Separation, Gibbstown, NJ). After 5 min equilibration, remifentanil and fentanyl were eluted with additional 5 ml methylene chloride. Organic solvent was evaporated to dryness at 45 degrees C under a gentle stream of nitrogen. The samples were reconstituted with 40-60 micro liter toluene, transferred to gas chromatography vials, which were loaded onto an autosampler, and 1-micro liter aliquots were injected into an HP-5890GC (Hewlett-Packard, Palo Alto, CA) equipped with a nitrogen-phosphorus detector operated at 250 degrees C. Injector temperature was maintained at 250 degrees Celsius. Separation was accomplished using fused silica megabore methyl silicone (HP-1) column (10 m x 0.53 mm ID, 2.65-micro meter film thickness; Hewlett-Packard). Oven temperature was kept isothermal at 235 degrees C for 14 min and then ramped to 270 degrees C, at 8 degrees C per min. The carrier and makeup gas for the detector was ultrapure grade helium at a flow of 6.5 ml/min, and 30 ml/min, respectively. Under these chromatographic conditions, remifentanil eluted at [approximately equal] 7.2 min and the internal standard (fentanyl) at [approximately equal] 11.2 min.
Standards and quality control samples were processed in the same fashion as described earlier using drug-free whole blood spiked with known concentrations of remifentanil (0-100 ng/ml). The concentrations of remifentanil in blood samples were calculated using the regression parameters obtained from the calibration curve. The lower limit of detection was 4.0 ng/ml and the coefficient of variation was 11.0% at 5 ng/ml, 6.8% at 50 ng/ml, and 5.0% at 100 ng/ml.
*Egan TD, Lemmens HJM, Fiset P, Muir KT, Hermann DJ, Stanski DR, Shafer SL: The pharmacokinetics and pharmacodynamics of GI87084B (abstract). ANESTHESIOLOGY 1992;77:A369.
**Glass PSA, Kapila A, Muir KT, Hermann DJ, Shiraishi M: A model to determine the relative potency of mu opioids: Alfentanil versus remifentanil (abstract). ANESTHESIOLOGY 1993;79:A378.
***Pitts MC, Palmore MM, Salmenpera MT, BA Kirkhart, CC Hug Jr: Pilot study: Hemodynamic effects of intravenous GI87084B in patients undergoing elective surgery (abstract). ANESTHESIOLOGY 1992;77:A101.
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Hall RI, Moldenhauer CC, Hug CC Jr: Fentanyl plasma concentrations maintained by simple infusion scheme in patients undergoing cardiac surgery. Anesth Analg 1993; 76:957-63.
James MK, Feldman PL, Schuster SV, Bilotta JM, Brackeen MF, Leighton HJ: Opioid receptor activity of GI87084B, a novel ultrashort-acting analgesic, in isolated tissues. J Pharmacol Exp Ther 1991; 259:712-8.
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Murphy MR, Hug CC Jr: The anesthetic potency of fentanyl in terms of its reduction of enflurane MAC. ANESTHESIOLOGY 1982; 57:485-8.
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Figure 1. Correlation between remifentanil infusion rate in micrograms per kilogram per minute and blood concentration of remifentanil in nanograms per milliliter using linear regression (R = 0.88).
Figure 1. Correlation between remifentanil infusion rate in micrograms per kilogram per minute and blood concentration of remifentanil in nanograms per milliliter using linear regression (R = 0.88).
Figure 1. Correlation between remifentanil infusion rate in micrograms per kilogram per minute and blood concentration of remifentanil in nanograms per milliliter using linear regression (R = 0.88).
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Figure 2. Remifentanil dose versus effect: infusion rate in micrograms per kilogram per minute versus percent reduction of enflurane minimum alveolar concentration relationship as analyzed by nonlinear regression. ED50is the dose causing 50% reduction of enflurane minimum alveolar concentration.
Figure 2. Remifentanil dose versus effect: infusion rate in micrograms per kilogram per minute versus percent reduction of enflurane minimum alveolar concentration relationship as analyzed by nonlinear regression. ED50is the dose causing 50% reduction of enflurane minimum alveolar concentration.
Figure 2. Remifentanil dose versus effect: infusion rate in micrograms per kilogram per minute versus percent reduction of enflurane minimum alveolar concentration relationship as analyzed by nonlinear regression. ED50is the dose causing 50% reduction of enflurane minimum alveolar concentration.
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Figure 3. Remifentanil concentration versus effect (blood concentration in nanograms per milliliter versus percent reduction of enflurane minimum alveolar concentration) relationship as analyzed by nonlinear regression. EC50is the concentration causing 50% reduction of enflurane minimum alveolar concentration.
Figure 3. Remifentanil concentration versus effect (blood concentration in nanograms per milliliter versus percent reduction of enflurane minimum alveolar concentration) relationship as analyzed by nonlinear regression. EC50is the concentration causing 50% reduction of enflurane minimum alveolar concentration.
Figure 3. Remifentanil concentration versus effect (blood concentration in nanograms per milliliter versus percent reduction of enflurane minimum alveolar concentration) relationship as analyzed by nonlinear regression. EC50is the concentration causing 50% reduction of enflurane minimum alveolar concentration.
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Figure 4. Heart rate and reduction of enflurane minimum alveolar concentration as functions of remifentanil dose rate in micrograms per kilogram per minute. Each line represents data for an individual animal (n = 6, the first set of experiments).
Figure 4. Heart rate and reduction of enflurane minimum alveolar concentration as functions of remifentanil dose rate in micrograms per kilogram per minute. Each line represents data for an individual animal (n = 6, the first set of experiments).
Figure 4. Heart rate and reduction of enflurane minimum alveolar concentration as functions of remifentanil dose rate in micrograms per kilogram per minute. Each line represents data for an individual animal (n = 6, the first set of experiments).
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Figure 5. Enflurane minimum alveolar concentration reduction with remifentanil over time: effect of 1.0 micro gram *symbol* kg sup -1 *symbol* min sup -1 (n = 8). Error bars represent+/-the SD.
Figure 5. Enflurane minimum alveolar concentration reduction with remifentanil over time: effect of 1.0 micro gram *symbol* kg sup -1 *symbol* min sup -1 (n = 8). Error bars represent+/-the SD.
Figure 5. Enflurane minimum alveolar concentration reduction with remifentanil over time: effect of 1.0 micro gram *symbol* kg sup -1 *symbol* min sup -1 (n = 8). Error bars represent+/-the SD.
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Figure 6. Consistency of enflurane minimum alveolar concentration reduction with remifentanil infusion of 1.0 (open circles) and 0.5 (dark circles) micro gram per kilogram per minute. Error bars show+/-SD for the eight dogs.
Figure 6. Consistency of enflurane minimum alveolar concentration reduction with remifentanil infusion of 1.0 (open circles) and 0.5 (dark circles) micro gram per kilogram per minute. Error bars show+/-SD for the eight dogs.
Figure 6. Consistency of enflurane minimum alveolar concentration reduction with remifentanil infusion of 1.0 (open circles) and 0.5 (dark circles) micro gram per kilogram per minute. Error bars show+/-SD for the eight dogs.
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Figure 7. Concentration in nanograms per milliliter of blood of the main metabolite of remifentanil (GR90291) over time (in min) in dogs receiving prolonged infusions of remtfentanil (n = 6). The dotted area represents the period where the remifentanil infusion was decreased by 50%. After measuring minimum alveolar concentration at this level, the remifentanil infusion was stopped.
Figure 7. Concentration in nanograms per milliliter of blood of the main metabolite of remifentanil (GR90291) over time (in min) in dogs receiving prolonged infusions of remtfentanil (n = 6). The dotted area represents the period where the remifentanil infusion was decreased by 50%. After measuring minimum alveolar concentration at this level, the remifentanil infusion was stopped.
Figure 7. Concentration in nanograms per milliliter of blood of the main metabolite of remifentanil (GR90291) over time (in min) in dogs receiving prolonged infusions of remtfentanil (n = 6). The dotted area represents the period where the remifentanil infusion was decreased by 50%. After measuring minimum alveolar concentration at this level, the remifentanil infusion was stopped.
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Table 1. Enflurane Minimum Alveolar Concentration Reduction in Dogs with Different Opioids
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Table 1. Enflurane Minimum Alveolar Concentration Reduction in Dogs with Different Opioids
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